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Interconnect Working Group

Interconnect Working Group. 2008 Edition 9 December 2008 Seoul Republic of Korea Christopher Case (The Linde Group), Osamu Yamazaki (Sharp), Larry Smith (SEMATECH), Jaeyoung Yang (Dongbu HiTek), Noh Jung Kwak (Hynix), Hyeondeok Lee (Samsung), Gilheyun Choi (Samsung), Scott List (SRC).

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Interconnect Working Group

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  1. Interconnect Working Group 2008 Edition 9 December 2008 Seoul Republic of Korea Christopher Case (The Linde Group), Osamu Yamazaki (Sharp), Larry Smith (SEMATECH), Jaeyoung Yang (Dongbu HiTek), Noh Jung Kwak (Hynix), Hyeondeok Lee (Samsung), Gilheyun Choi (Samsung), Scott List (SRC)

  2. ITWG Regional Chairs Japan Hideki Shibata Nobuo Aoi Taiwan Douglas CH Yu US Christopher Case Europe Hans-Joachim Barth Alexis Farcy Korea Hyeondeok Lee Sibum Kim

  3. Robert Geffken Hans-Joachim Barth Alexis Farcy Harold Hosack Paul Feeney Rick Reidy Mauro Kobrinsky Hideki Shibata Kazuyoshi Ueno Michele Stucchi Eiichi Nishimura Robin Cheung Didier Louis Katsuhiko Tokushige Masayoshi Imai JD Luttmer Morihiro Kada Akira Ouchi Greg Smith Detlef Weber Thomas Toms Anderson Liu Scott List Osamu Yamazaki Nobuo Aoi Scott Pozder Koji Ban Masayuki Hiroi Manabu Tsujimura Nohjung Kwak Hyeon Deok Lee Sibum Kim Lucile Arnaud Sitaram Arkalgud Azad Naeemi Dirk Gravesteijn NS Nagaraj Mike Mills Yuichi Nakao Larry Smith Skip Berry Yasushi Igarashi Gunther Schindler Chung-Liang Chang Tomoji Nakamura Shuhei Amakawa Eric Beyne Christopher Case Partial List of Contributors

  4. Agenda • Scope and structure • Technology requirements • Difficult challenges • Energy and performance • Low k roadmap • Interconnect for memory • DRAM wiring roadmap • Non-volatile interconnect requirements • Beyond metal/dielectric systems • 3D, optical and carbon nanotubes (CNT) • High Density TSV Technology • 2009 Preview • Last words

  5. Interconnect scope • Conductors and dielectrics • Starts at contact • Metal 1 through global levels • Includes the pre-metal dielectric (PMD) • Associated planarization • Necessary etch, strip and cleans • Embedded passives • Reliability and system and performance issues • Ends at the top wiring bond pads • “Needs” based replaced by – scaled, equivalently scaled or functional diversity drivers

  6. Technology Requirements • Now restated and organized as • General requirements • Resistivity • Dielectric constant • Metal levels • Reliability metrics • Level specific requirements (M1, intermediate, global) • Geometrical • Via size and aspect ratio • Barrier/cladding thickness • Planarization specs • Materials requirements • Conductor effective resistivity and scattering effects • Electrical characteristics • Delay, capacitance, crosstalk, power index

  7. Technology Drivers Expanding • Scaled solutions • Traditional geometric scaling • Cost • necessary to enable transistor scaling). • Performance • dielectric constant scaling for delay, and power improvements. • Reliability • EM • crosstalk • Functional diversity • Increasing value by adding functionality using CMOS-compatible solutions: • 3D, optical components, sensors. • Contributing to More than Moore

  8. Difficult challenges (1 of 3) • Meeting the requirements of scaled metal/dielectric systems • Managing RC delay and power • New dielectrics (including air gap) • Controlling conductivity (liners and scattering) • Filling small features • Liners • Conductor deposition • Reliability • Electrical and thermo-mechanical • Engineering a manufacturable interconnect stack compatible with new materials and processes • Defects • Metrology • Variability

  9. Difficult challenges (2 of 3) • Meeting the requirements with equivalent scaling • Interconnect design and architecture (includes multi-core benefits) • Alternative metal/dielectric assemblies • 3D with TSV • Interconnects beyond metal/dielectrics • 3D • Optical wiring • CNT/Graphene • Reliability • Electrical and thermo-mechanical • Engineering a CMOS-compatible manufacturable interconnect system • Non-traditional materials (for optical, CNT etc.) • Unique metrology (alignment, chirality measurements, turning radius etc)

  10. Difficult challenges (3 of 3) • Adding functional diversity • Intelligent Interconnect • Active devices embedded in the interconnect BEOL • Mixed technologies Si, GaAs, HgCdTe together • Mixed signalling approaches • RF and analog • Passive devices • Repeaters in interconnect, combined metallic/semiconducting CNT interconnects • Back-end memory • Variable resistor via • Reliability • Electrical and thermo-mechanical • Engineering a CMOS-compatible manufacturable interconnect system • Non-traditional materials III/V, II/VI • Deposition (low temperature epi) • Unique metrology (composition)

  11. Dynamic Power • Increasing concern about rising dynamic power in the interconnect stack • Interconnects make a significant contribution to total dynamic power • Impacts effective k roadmap • Drives reduction in parasitic capacitance • Dynamic power is a key constraint for high performance MPUs • Alternative interconnect technologies (optical, CNT, RF, etc.) should be performance competitive in terms of delay and power • Influence of number of functions (N), activity (A) and frequency (F): P = (NAF)CV2

  12. Table INTC2 (MPU and ASIC Interconnect Technology Requirements—Near-term Years) Power index = C Vdd2 a (1 GHz) ew (1 cm2)/p; p = pitch; Vdd = supply voltage; ew = wiring efficiency = 1/3; a = activity factor = 0.03. The calculated values are an approximation for the “power per GHz per cm2 of metallization layer”. This index scales with the critical parameters that determine the interconnect dynamic power. NOTES: the values provided are an average for M1, Intermediate and Global interconnects. The range of values results from the maximum and minimum effective dielectric constants.

  13. ITRS2003 ITRS2005 ITRS2007-2008 ITRS2005 Effective Dielectric Constant; keff ITRS2001 ITRS1999 Year of 1st Shipment Historical Transition of ITRS Low-k Roadmap

  14. Integration Schemes

  15. Company 90 nm 65 nm45 nm 32nm ー ー I CVD SiOC DD (k=2.9) CVD SiOC DD (k=2.9) ー ー I CVD SiOC DD (k=2.75) CVD SiOC DD (k=2.45) CVD SiOC DD (k=3.0) ー T CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.2-2.3)? CVD SiOC DD (k=2.7) CVD SiOC DD (k=2.55)? ー R CVD SiOC stack DD (k=2.6/3.0) CVD SiOC DD (k=2.9) CVD SiOC DD (k=2.65) ー F NCS/NCS stack DD (k=2.25/2.25)? NCS/NCS stack DD (k=2.25/2.25) NCS/CVD SiOC stack DD (k=2.25/2.9) CVD SiOC DD (k=2.9) T P-PAr/p-SiOC hybrid DD (k=2.3/2.3) PAr/SiOC hybrid DD (k=2.6/2.5) ULK-PAr/SiOC hybrid DD (k=2.0/2.0) CVD SiOC DD (k=2.9) Low-k Trend from Conference Papers (2003-2007 IITC, IEDM, VL, AMC) Slow down of low-k technology development speed and large variation of k values among device companies

  16. Actual Low-k Trend from Introduction in Manufacturing 90 nm 65 nm45 nm32nm CVD SiOC DD (k=2.2-2.3)? CVD SiOC DD (k=3.0) CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.55)? CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.8) CVD SiOC DD (k=2.6) CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.4) CVD SiOC DD (k=3.0) CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.8) CVD SiOC DD (k=3.0) CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.75) CVD SiOC DD (k=2.4) CVD SiOC DD (k=3.0) CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.75) CVD SiOC DD (k=2.4) CVD SiOC DD (k=3.0) CVD SiOC DD (k=3.0) CVD SiOC DD (k=2.8) CVD SiOC DD (k=2.4)? Actual introduction in manufacturing of low-k material is one generation delayed and a variation of bulk k range among device makers is narrowing compared with trend from conference papers

  17. ITRS2008 Low-k Roadmap Update Change maximum bulk k value from 2.9 to 2.8 corresponding to 45nm actual introduction in manufacturing of low-k material. Beyond 2009, decrease maximum bulk k value by 0.1. 2.3-2.7 → 2.3-2.6 @2009-2011 2.1-2.5 → 2.1-2.4 @2012-2014 1.9-2.3 → 1.9-2.2 @2015-2017 1.7-2.1 → 1.7-2.0 @2018-2020 1.5-1.9 → 1.5-1.8 @2021-2023 2.5-2.9 → 2.5-2.8 @2007-2008

  18. 2008 Low k update • For those who think changes in k of 0.1 are significant – we aim to please • For those who don’t – try reaching consensus on low k with 100 people • Proliferation of air-gap approaches • Values of effective k-value down to 1.7 with low crosstalk levels • Localized air gaps to maintain good thermal and mechanical properties

  19. 2008 Barrier/Nucleation/Resistivity • ALD barrier processes and metal capping layers for Cu are lagging in introduction • Resistivity increases due to scattering and impact of liners • No known practical solutions

  20. DRAM Small changes in specific via and contact resistivity Contact A/R (stacked capacitor) rises to >40 in 2014 - a red challenge - associated with the 40 nm DRAM half pitch High A/R Contact Interconnect and HAC FEP – now matched Cu implemented in 2007 Latest view - low k with an effective dielectric constant of 3.1 – 3.4 pushed back 3 years to 2011 Plan to distinguish embedded, flash, and traditional DRAM along with alternative memory in the interconnect in the future (2009)

  21. Revised DRAM

  22. Jmax 2008 Inverter circuit (F.O=4) -Minimum Tr width (Wmin.): NMOS Gate width= (ASIC Half-pitch)x 4 PMOS Gate width=(NMOS Gate-width) x 2 -Tr-width (Wg): Wg =Wmin.x 2 -Gate capacitance (Cg) -Wiring length (Li): IM-Pitch x 400 -Wiring capacitance (Ci): Updated keff Vdd Cg*Wg Critical point Imax Ci Cg*Wg Fan out N=4 Current density of IM-interconnect (Jmax) = f (Cg*Wg *N+Ci) *Vdd/(Wi*Ti) Intermediate wire Critical points for the DC pulse current, where the minimum pitch and via-size are used for high density. Frequency plans matched with design. Currently revising two key inputs to Jmax models: critical wire lengths, load assumptions and validating technology maturity color shading

  23. Jmax 2007 Jmax 2008 Jmax Update - 2008 Small changes from 2007 Jmax values

  24. Emerging Interconnect (1/2) • Use geometry • 3D • Air gap • Use different signaling methods • Signal design • Signal coding techniques  • Use innovative design and package options • Interconnect - centric design • Package intermediated interconnect  • Chip-package co-design  Figure From Stanford

  25. Emerging interconnect (2/2) • Use different physics • Optics (waveguides, emitters, detectors, free space, trans-impedance amps, modulators) • RF/microwaves (transmitters, receivers, free space, waveguides) • Terahertz photonics • Radical solutions • Nanowires/nanotubes/graphene • Molecules • Spintronics • Quantum wave functions 

  26. From low-k to no k - air gaps • Introduction of air gap architectures • Creation of air gaps with non-conformal deposition • Removal of sacrificial materials after multi-level interconnects • Values of effective k-value down to 1.7 with low crosstalk levels • Localized air gaps to maintain good thermal and mechanical properties Ultra-low kand Air gap (k<1.7) (CVD and Spin-on)

  27. Hypothetical On-die Optical Interconnects with WDM Wavelength specific modulator … s1 s1 s2 s2 s3 Waveguide s2 s4 s4 s4 s5 s6 s6 Intel Technology Journal, Volume 8, Issue 2, 2004

  28. High Density TSV Roadmap or“enabling terabits/sec at femtojoules” • The Interconnect perspective - examples: • High bandwidth/low energy interfaces between memory and logic • Heterogeneous integration with minimal parasitics (analog/digital, mixed substrate materials, etc.) • “Re-architect” chip by placing macros (functional units) on multiple tiers (wafers) and connect using HD TSVs • Model assumptions: • TSV diameter limited by silicon thickness and TSV Aspect Ratio: • Pitch limited by TSV diameter, misalignment tolerance, minimum pad spacing

  29. High Density TSV Technology

  30. High Density TSV Specification • Represents devices that could appear in production, using at least one approach to 3D integration • ≤10 mm Si thickness, wafer-to-wafer integration, wafers thinned after bonding

  31. INTC6 High Density Through Silicon Specification

  32. Summary of Notable 2008 changes • Low-k slowdown • New range for MPU/ASIC bulk k and keff • DRAM keff of 3.1-3.4 delayed 3 yrs to 2009 • New Technology Introduction • ALD barrier processes and metal capping layers for Cu are lagging in introduction. • No solutions seen for Cu resistivity rise - managed • Power Metric • Capacitance per unit length decreases due to decreases of the dielectric constant. • The dynamic power is expected to increase because of the increased number of metallization layers, larger chip size and increased frequency.

  33. 2009 Preview • 3DIC Definition and Coordination • Work with Design to conduct an industry survey to determine 3D design requirements by application area • Improve coordination with A&P • Identify factors contributing to yield loss • Work with Design and Test to identify issues with HD TSV • Emerging Technologies Expansion • Identify new options with ERM TWG • More than Moore Category Standardization • Work with other TWGs to define a common set of More than Moore categories

  34. More Moore • Must manage the power envelope • Must continue to meet requirements of scaled metal/dielectric systems while developing CMOS-compatible equivalent scaling solutions • Cu resistivity impact real but manageable • materials solutions alone cannot deliver performance - end of traditional scaling • More than Moore • integrated system approach required • functional diversity enhances value • Focus on 3DIC and emerging interconnect Last words

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